Air circulating disinfection shoe cabinet
By installing a circulating disinfection device in the shoe cabinet, which includes a fan, filter, ultraviolet disinfection lamp, and photocatalytic mesh, the problems of incomplete disinfection and difficulty in removing odors in traditional shoe cabinets are solved. This achieves efficient air circulation, purification, and drying, thus improving the storage environment for shoes.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU MODERN Z FURNITURE CO LTD
- Filing Date
- 2025-06-20
- Publication Date
- 2026-07-03
Smart Images

Figure CN224440702U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of home storage and disinfection technology, and in particular to an air-circulating disinfection shoe cabinet. Background Technology
[0002] Currently, traditional shoe cabinets have a relatively simple function, mainly used for storing shoes, and cannot meet people's needs for shoe disinfection, deodorization, and drying. Some shoe cabinets with disinfection functions are not very effective, only using simple ultraviolet irradiation or ozone disinfection inside the cabinet, without effective air circulation, resulting in incomplete disinfection and failure to fully remove odors and moisture, affecting the storage quality and lifespan of the shoes.
[0003] Therefore, it is necessary to design a new type of shoe cabinet with an internal air circulation and disinfection effect. Utility Model Content
[0004] The purpose of this invention is to provide an air-circulating disinfection shoe cabinet. Through a unique structural design, it achieves efficient air circulation inside the shoe cabinet, disinfecting, deodorizing, and drying the air during the circulation process, thereby improving the shoe storage environment and solving the problems of incomplete disinfection and difficulty in removing odors in traditional shoe cabinets.
[0005] To achieve the above objectives, the present invention adopts the following technical solution:
[0006] An air-circulating disinfection shoe cabinet includes a cabinet body and a control device. The interior of the cabinet body is divided by a partition to form two symmetrically distributed storage chambers. The front end of the cabinet body is provided with a door panel to cover the storage chambers. A circulation disinfection device is provided between the two storage chambers. The circulation disinfection device includes an outer shell and a fan, a filter, an ultraviolet disinfection lamp, and a photocatalytic screen arranged sequentially from bottom to top in the inner cavity of the outer shell. The outer shell has an air inlet pipe at the end near the fan and an air outlet pipe at the end near the photocatalytic screen. The top of the storage chamber has an air inlet and the bottom of the storage chamber has an air outlet. The air inlet pipe is connected to the air outlet through an air inlet pipe, and the air outlet pipe is connected to the air inlet through an air outlet pipe.
[0007] Furthermore, the interior of the housing is provided with a support frame for fixing the ultraviolet disinfection lamp and the photocatalytic mesh. The support frame includes a fixing plate and several support rods connected to the outer periphery of the fixing plate. The ultraviolet disinfection lamp is vertically installed in the middle of the fixing plate, and the photocatalytic mesh is conical and distributed around the ultraviolet disinfection lamp.
[0008] Furthermore, the photocatalytic mesh is a metal mesh with nano-titanium dioxide coated on its surface.
[0009] Furthermore, the filter screen is an activated carbon fiber filter screen.
[0010] Furthermore, the storage cavity is provided with a tray, and the tray has ventilation holes evenly distributed on it.
[0011] Furthermore, the diameter of the ventilation hole is 3mm to 10mm.
[0012] Furthermore, the storage cavity has several horizontal guide grooves symmetrically arranged on both sides of its sidewalls, and the edge of the tray has a baffle. The tray has symmetrically arranged first rotating shafts on both sides of the end near the baffle, and symmetrically arranged second rotating shafts on both sides of the end away from the baffle. The first rotating shafts and the second rotating shafts are slidably connected to the corresponding horizontal guide grooves.
[0013] Furthermore, the air inlet is provided with an air drying component, which includes a desiccant box with a placement cavity and a cover plate that covers the placement cavity. The placement cavity is filled with desiccant, and both the desiccant box and the cover plate have uniformly distributed through holes.
[0014] Furthermore, the desiccant box is connected to the edge of the air inlet via a magnetic attraction device. The magnetic attraction device includes a first magnet block disposed on the desiccant box and a second magnet block disposed on the cabinet. The first magnet block and the second magnet block are magnetically attracted to each other.
[0015] Furthermore, the control device includes a control panel fixed to the front surface of the cabinet. The control panel has several operating switches, and the operating switches, the fan, and the ultraviolet disinfection lamp are respectively connected to the control panel.
[0016] Compared with the prior art, this utility model provides an air-circulating disinfection shoe cabinet, which has the following beneficial effects:
[0017] This invention achieves efficient internal air circulation within the shoe cabinet through a circulating disinfection device, effectively solving the problems of incomplete disinfection and difficulty in removing odors inherent in traditional shoe cabinets. The independent design of each storage compartment allows for flexible storage based on the quantity and type of shoes. Simultaneously, during air circulation, the synergistic effect of the filter, ultraviolet disinfection lamp, photocatalytic mesh, and air drying components thoroughly removes impurities, bacteria, viruses, and odors from the air, maintaining a fresh and dry environment inside the shoe cabinet, extending the lifespan of shoes, and providing users with a healthy and comfortable shoe storage environment. Attached Figure Description
[0018] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention from a first-view perspective.
[0020] Figure 2 This is a three-dimensional structural diagram of the present invention from a second perspective.
[0021] Figure 3 This is a schematic diagram of the air drying assembly.
[0022] Figure 4 A schematic diagram of air recirculation disinfection;
[0023] Figure 5 This is a schematic diagram of the circulating disinfection device;
[0024] Figure 6 A schematic diagram showing the ultraviolet disinfection lamp and photocatalytic mesh fixed on the support frame;
[0025] Figure 7 This is a schematic diagram of the three-dimensional structure of the tray.
[0026] Reference numerals: 1. Cabinet; 11. Partition; 12. Storage cavity; 121. Air inlet; 122. Air outlet; 123. Horizontal guide rail; 13. Door panel; 14. Second magnet; 2. Control device; 21. Control panel; 22. Operating switch; 3. Circulating disinfection device; 31. Outer shell; 311. Air inlet pipe; 312. Air outlet pipe; 32. Fan; 33. Filter screen; 34. Ultraviolet disinfection lamp; 35. Photocatalytic screen; 36. Support frame; 361. Fixing plate; 362. Support rod; 4. Air inlet pipe; 5. Air outlet pipe; 6. Tray; 61. Ventilation hole; 62. Baffle; 63. First rotating shaft; 64. Second rotating shaft; 7. Air drying assembly; 71. Desiccant box; 72. Cover plate; 73. Through hole; 74. First magnet. Detailed Implementation
[0027] The technical solution of this utility model will be clearly and completely described below through detailed embodiments and in conjunction with the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this utility model, and not all of them. Based on the embodiments of this utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of this utility model.
[0028] Please refer to Figures 1-7 This embodiment provides an air-circulating disinfection shoe cabinet, including a cabinet body 1 and a control device 2. The interior of the cabinet body 1 is divided by a partition 11 to form two symmetrically distributed storage chambers 12. The two storage chambers 12 are independent of each other and can be flexibly stored according to the number and type of shoes. The front end of the cabinet body 1 is provided with a door panel 13 to cover the storage chambers 12. A circulating disinfection device 3 is installed between the two storage chambers 12. The circulating disinfection device 3 includes a housing 31 and, within the inner cavity of the housing 31, a fan 32, a filter 33, an ultraviolet disinfection lamp 34, and a photocatalytic mesh 35 arranged sequentially from bottom to top. The housing 31 has an air inlet pipe 311 at the end near the fan 32 and an air outlet pipe 312 at the end near the photocatalytic mesh 35. The top of the storage chamber 12 has an air inlet 121, and the bottom of the storage chamber 12 has an air outlet 122. The air inlet pipe 311 is connected to the air outlet 122 via an air inlet pipe 4, and the air outlet pipe 312 is connected to the air inlet 121 via an air outlet pipe 5. By forming a complete air circulation loop, when the fan is started, the air inside the shoe cabinet enters the circulating disinfection device through the air outlet and air inlet pipe for filtration, disinfection, and purification, and then returns to the inside of the shoe cabinet through the air outlet and air inlet pipe, thus achieving internal air circulation.
[0029] In some embodiments, as an example, the outer casing 31 is made of ABS engineering plastic, which has good corrosion resistance and mechanical strength; the fan 32 is a centrifugal fan, which has a large air volume and low noise, and can efficiently extract the air inside the shoe cabinet and send it into the circulating disinfection device; the filter screen 33 is an activated carbon fiber filter screen, which can effectively filter out large particulate impurities such as dust and hair in the air; the ultraviolet disinfection lamp 34 is a low-pressure mercury lamp with a wavelength of 253.7nm, which can effectively destroy the DNA structure of bacteria and viruses to achieve the purpose of sterilization and disinfection; the photocatalytic mesh 35 is a metal mesh with nano-titanium dioxide coated on its surface. The photocatalytic mesh uses nano-titanium dioxide as a photocatalyst and uses ultraviolet irradiation to generate highly oxidizing free radicals, which decompose odor molecules and organic pollutants in the air to achieve air purification.
[0030] In some implementations, reference Figures 4-6 The housing 31 contains a support frame 36 for fixing the ultraviolet disinfection lamp 34 and the photocatalytic mesh 35. Specifically, the support frame is made of corrosion-resistant material to ensure the service life of the device. As an example, the support frame is made of stainless steel, which has good corrosion resistance and mechanical strength, ensuring stable operation of the device.
[0031] In some specific implementation methods, such as Figure 6As shown, the support frame 36 includes a fixed plate 361 and several support rods 362 connected to the outer periphery of the fixed plate 361. The ultraviolet disinfection lamp 34 is vertically installed in the middle of the fixed plate 361. The photocatalytic mesh 35 is cone-shaped and distributed around the ultraviolet disinfection lamp 34. This layout has a high disinfection effect.
[0032] In some implementations, reference Figure 1 , Figure 2 , Figure 4 and Figure 7 The storage cavity 12 is provided with a tray 6 for placing shoes. The tray 6 has ventilation holes 61 evenly distributed to facilitate the flow of air inside the storage cavity, making the air circulation more uniform and efficient.
[0033] As an example, the diameter of the ventilation hole 61 is 3mm to 10mm, which is conducive to the uniform flow of air inside the storage cavity and ensures that each pair of shoes is in a good air circulation environment.
[0034] In some specific implementation methods, refer to Figure 1 , Figure 4 and Figure 7 The storage cavity 12 has several symmetrically arranged horizontal guide grooves 123 on its two side walls, spaced vertically. The edge of the tray 6 is provided with a baffle 62. The tray 6 has symmetrically arranged first pivot sections 63 on both sides near the baffle 62, and symmetrically arranged second pivot sections 64 on both sides away from the baffle 62. The first pivot sections 63 and second pivot sections 64 are slidably connected to the corresponding horizontal guide grooves 123. This allows the tray to be pulled out and its height adjusted, thus setting the space size according to different types of shoes. For example, a tray with a larger spacing is used to store large shoes such as boots; a tray with a medium spacing is used to store everyday leather shoes and athletic shoes; and a tray with a smaller spacing is used to store children's shoes or slippers. Furthermore, the first and second pivot sections on the same tray can be slid into two horizontal guide grooves of different heights, allowing the tray to support the shoes in an inclined position for easy retrieval.
[0035] As an improved implementation method, refer to Figures 2-4 The air inlet 121 is equipped with an air drying assembly 7, which includes a desiccant box 71 with a placement cavity and a cover plate 72 that covers the placement cavity. The placement cavity is filled with desiccant, and both the desiccant box 71 and the cover plate 72 have evenly distributed through holes 73. As an example, silica gel desiccant can be used, which can absorb moisture in the air and keep the air dry.
[0036] In some specific implementation methods, refer to Figures 2-4 The desiccant box 71 is connected to the edge of the air inlet 121 via a magnetic attraction device. The magnetic attraction device includes a first magnet 74 disposed on the desiccant box 71 and a second magnet 14 disposed on the cabinet 1. The first magnet 74 and the second magnet 14 are magnetically attracted to each other. The magnetic attraction device allows for quick installation and removal of the desiccant box.
[0037] In some specific implementation methods, refer to Figure 1 The control device 2 includes a control panel 21 fixed to the front surface of the cabinet 1. The control panel 21 has several operating switches 22, and the operating switches 22, the fan 32, and the ultraviolet disinfection lamp 34 are respectively connected to the control panel 21. The control panel has a built-in control circuit, and the operating parameters of the fan and the ultraviolet disinfection lamp can be preset or adjusted by pressing the operating switches.
[0038] refer to Figures 1-7 The working process is as follows: First, adjust the position of the tray 6 according to the height of the shoes, then place the shoes on the tray 6 inside the storage cavity 12 and close the door 13. Start the circulating disinfection device 3; the fan 32 will begin running, drawing air from inside the cabinet 1 into the circulating disinfection device 3 through the air intake pipe 4. The air first enters the filter 33, filtering out large particles, and then passes through the ultraviolet disinfection lamp 34 and the photocatalytic mesh 35 for disinfection and purification. The treated air returns to the storage cavity 12 inside the cabinet 1 through the air outlet pipe 5 and the air inlet 121, thus continuously purifying the air inside the shoe cabinet. Simultaneously, the air drying component 7 dries the circulating air, ensuring the air inside the shoe cabinet is fresh and dry, providing a good storage environment for the shoes.
[0039] The above embodiments are merely illustrative of the concept and technical solution of this utility model, and are not intended to limit this utility model. Any person skilled in the art can modify or alter the above embodiments without departing from the spirit and scope of this utility model. Therefore, all equivalent modifications or alterations made by those skilled in the art without departing from the spirit and technical concept disclosed in this utility model should still be covered by the claims of this utility model.
[0040] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. An air recirculation disinfecting shoe cabinet comprising a cabinet body and a control device, characterized in that, The cabinet's interior is divided by a partition into two symmetrically distributed storage chambers. The front face of the cabinet is fitted with a door panel to cover the storage chambers. A circulating disinfection device is installed between the two storage chambers. This device includes an outer shell and, within the inner cavity of the outer shell, a fan, a filter, an ultraviolet disinfection lamp, and a photocatalytic screen, arranged sequentially from bottom to top. The outer shell has an air inlet pipe near the fan and an air outlet pipe near the photocatalytic screen. Each storage chamber has an air inlet at the top and an air outlet at the bottom. The air inlet pipe is connected to the air outlet via an air inlet pipe, and the air outlet pipe is connected to the air inlet via an air outlet pipe.
2. The air-circulating disinfectant shoe cabinet according to claim 1, wherein, The interior of the housing is provided with a support frame for fixing the ultraviolet disinfection lamp and the photocatalytic mesh. The support frame includes a fixing plate and several support rods connected to the outer periphery of the fixing plate. The ultraviolet disinfection lamp is vertically installed in the middle of the fixing plate, and the photocatalytic mesh is conical and distributed around the ultraviolet disinfection lamp.
3. The air-circulating disinfecting shoe cabinet according to claim 2, wherein, The photocatalytic mesh is a metal mesh with nano-titanium dioxide coated on its surface.
4. The air-circulating disinfecting shoe cabinet according to claim 2, wherein, The filter screen is an activated carbon fiber filter screen.
5. The air-circulating sterilizing shoe cabinet according to claim 1, wherein, The storage cavity is equipped with a tray, and the tray has ventilation holes evenly distributed on it.
6. The air-circulating disinfecting shoe cabinet according to claim 5, wherein, The diameter of the ventilation hole is 3mm to 10mm.
7. The air-circulating sterilizing shoe cabinet according to claim 5, wherein, The storage cavity has several horizontal guide grooves symmetrically arranged on both sides of its sidewalls. The edge of the tray is provided with a baffle. The tray has symmetrically arranged first rotating shafts on both sides of the end near the baffle and symmetrically arranged second rotating shafts on both sides of the end away from the baffle. The first rotating shafts and the second rotating shafts are slidably connected to the corresponding horizontal guide grooves.
8. The air-circulating disinfecting shoe cabinet of claim 1, wherein, The air inlet is equipped with an air drying component, which includes a desiccant box with a placement cavity and a cover plate that covers the placement cavity. The placement cavity is filled with desiccant, and both the desiccant box and the cover plate have evenly distributed through holes.
9. The air-circulating disinfecting shoe cabinet according to claim 8, wherein, The desiccant box is connected to the edge of the air inlet via a magnetic attraction device. The magnetic attraction device includes a first magnet block disposed on the desiccant box and a second magnet block disposed on the cabinet. The first magnet block and the second magnet block are magnetically attracted to each other.
10. The air-circulating disinfection shoe cabinet according to any one of claims 1 to 9, characterized in that, The control device includes a control panel fixed to the front surface of the cabinet. The control panel has several operating switches, and the operating switches, the fan, and the ultraviolet disinfection lamp are respectively connected to the control panel.